Skip to search form
Skip to main content
Skip to account menu
Semantic Scholar
Semantic Scholar's Logo
Search 223,624,882 papers from all fields of science
Search
Sign In
Create Free Account
Chenopodiaceae
The goosefoot plant family of the order Caryophyllales, subclass Caryophyllidae, class Magnoliopsida. It includes beets and chard (BETA VULGARIS), as…
Expand
National Institutes of Health
Create Alert
Alert
Related topics
Related topics
11 relations
Amaranthaceae
Microbiological
aspects of radiation effects
physiological aspects
Broader (1)
Angiosperms
Narrower (6)
Goosefoot
Halogeton
Kochia <plant>
Salicornia
Expand
Papers overview
Semantic Scholar uses AI to extract papers important to this topic.
Highly Cited
2009
Highly Cited
2009
Mercury intracellular partitioning and chelation in a salt marsh plant, Halimione portulacoides (L.) Aellen: strategies underlying tolerance in environmental exposure.
M. Válega
,
A. Lima
,
E. Figueira
,
E. Pereira
,
M. Pardal
,
A. Duarte
Chemosphere
2009
Corpus ID: 12262124
Highly Cited
2008
Highly Cited
2008
Sensitive response of desert vegetation to moisture change based on a near-annual resolution pollen record from Gahai Lake in the Qaidam Basin, northwest China
Yan Zhao
,
Zicheng Yu
,
Zicheng Yu
,
Fahu Chen
,
Xiuju Liu
,
E. Ito
2008
Corpus ID: 40471067
2007
2007
Sequence variation within Beet necrotic yellow vein virus p25 protein influences its oligomerization and isolate pathogenicity on Tetragonia expansa.
E. Klein
,
D. Link
,
A. Schirmer
,
M. Erhardt
,
D. Gilmer
Virus Research
2007
Corpus ID: 33072008
Highly Cited
2006
Highly Cited
2006
The Cytoskeleton Maintains Organelle Partitioning Required for Single-Cell C4 Photosynthesis in Chenopodiaceae Species[W]
S. D. Chuong
,
V. Franceschi
,
G. Edwards
The Plant Cell Online
2006
Corpus ID: 5091954
Recently, three Chenopodiaceae species, Bienertia cycloptera, Bienertia sinuspersici, and Suaeda aralocaspica, were shown to…
Expand
2004
2004
Neogene vegetation of the Meyer Desert Formation ( Sirius Group ) Transantarctic Mountains , Antarctica
Allan C. Ashwortha
,
David J. Cantrillb
2004
Corpus ID: 53468391
Highly Cited
2003
Highly Cited
2003
Development of biochemical specialization and organelle partitioning in the single-cell C4 system in leaves of Borszczowia aralocaspica (Chenopodiaceae).
E. Voznesenskaya
,
G. Edwards
,
O. Kiirats
,
E. Artyusheva
,
V. Franceschi
American-Eurasian journal of botany
2003
Corpus ID: 31120979
The terrestrial plant Borszczowia aralocaspica (Chenopodiaceae) has recently been shown to contain the entire C(4) photosynthesis…
Expand
Highly Cited
2002
Highly Cited
2002
Lateglacial and early Holocene vegetation development in the Gutaiului Mountains, northwestern Romania.
L. Björkman
,
A. Feurdean
,
Kajsa Cinthio
,
B. Wohlfarth
,
G. Possnert
2002
Corpus ID: 58927964
Highly Cited
2002
Highly Cited
2002
Effects of sodium, magnesium and calcium salts on seed germination and radicle survival of a halophyte, Kalidium caspicum (Chenopodiaceae)
Kazuo Tobe
,
Xiaoming Li
,
K. Omasa
2002
Corpus ID: 56337664
Kalidium caspicum (L.) Ung.-Sternb. is a common species of highly saline habitats of north-western China, which in previous…
Expand
1985
1985
Cross-reactivity among Chenopodiaceae and Amaranthaceae.
M. Lombardero
,
O. Duffort
,
J. G. Sellés
,
J. Hernández
,
J. Carreira
Annals of allergy
1985
Corpus ID: 28708737
Pollen extracts from Atriplex latifolia, Beta vulgaris, Salsola kali and Amaranthus retroflexus were compared with an extract…
Expand
Highly Cited
1981
Highly Cited
1981
Myrmecochory in some plants (F. chenopodiaceae) of the Australian arid zone
D. Davidson
,
S. Morton
Oecologia
1981
Corpus ID: 21624591
SummarySeveral common plants (Chenopodiaceae) of the Australian arid zone produce diaspores that bear small and inconspicuous…
Expand
By clicking accept or continuing to use the site, you agree to the terms outlined in our
Privacy Policy
(opens in a new tab)
,
Terms of Service
(opens in a new tab)
, and
Dataset License
(opens in a new tab)
ACCEPT & CONTINUE